Here's a `MWE` of a much larger code I'm using. It performs a Monte Carlo integration over a KDE (kernel density estimate) for all values located below a certain threshold (the integration method was suggested over at this question: Integrate 2D kernel density estimate) iteratively for a number of points in a list and returns a list made of these results.

``````import numpy as np
from scipy import stats
from multiprocessing import Pool

# Define KDE integration function.
def kde_integration(m_list):

# Put some of the values from the m_list into two new lists.
m1, m2 = [], []
for item in m_list:
# x data.
m1.append(item[0])
# y data.
m2.append(item[1])

# Define limits.
xmin, xmax = min(m1), max(m1)
ymin, ymax = min(m2), max(m2)

# Perform a kernel density estimate on the data:
x, y = np.mgrid[xmin:xmax:100j, ymin:ymax:100j]
values = np.vstack([m1, m2])
kernel = stats.gaussian_kde(values)

# This list will be returned at the end of this function.
out_list = []

# Iterate through all points in the list and calculate for each the integral
# of the KDE for the domain of points located below the value of that point
# in the KDE.
for point in m_list:

# Compute the point below which to integrate.
iso = kernel((point[0], point[1]))

# Sample KDE distribution
sample = kernel.resample(size=1000)

#Choose number of cores and split input array.
cores = 4
torun = np.array_split(sample, cores, axis=1)

# Print number of active threads.

#Calculate
pool = Pool(processes=cores)
results = pool.map(kernel, torun)

#Reintegrate and calculate results
insample_mp = np.concatenate(results) < iso

# Integrate for all values below iso.
integral = insample_mp.sum() / float(insample_mp.shape[0])

# Append integral value for this point to list that will return.
out_list.append(integral)

return out_list

# Generate some random two-dimensional data:
def measure(n):
"Measurement model, return two coupled measurements."
m1 = np.random.normal(size=n)
m2 = np.random.normal(scale=0.5, size=n)
return m1+m2, m1-m2

# Create list to pass to KDE integral function.
m_list = []
for i in range(100):
m1, m2 = measure(5)
m_list.append(m1.tolist())
m_list.append(m2.tolist())

# Call KDE integration function.
print 'Integral result: ', kde_integration(m_list)
``````

The `multiprocessing` in the code was suggested over at this question Speed up sampling of kernel estimate to speed up the code (which it does up to ~3.4x).

The code works ok until I try to pass to the KDE function a list of more than ~62-63 elements (ie: I set a value over 63 in the line `for i in range(100)`) If I do that I get the following error:

``````Traceback (most recent call last):
File "~/gauss_kde_temp.py", line 78, in <module>
print 'Integral result: ', kde_integration(m_list)
File "~/gauss_kde_temp.py", line 48, in kde_integration
pool = Pool(processes=cores)
File "/usr/lib/python2.7/multiprocessing/__init__.py", line 232, in Pool
File "/usr/lib/python2.7/multiprocessing/pool.py", line 144, in __init__
self._worker_handler.start()
File "/usr/lib/python2.7/threading.py", line 494, in start
``````

usually (9 out of 10 times) around the active thread `374`. I'm way out of my league in terms of `python` coding here and I have no clue as to how I could fix this issue. Any help will be much appreciated.

I tried adding a `while` loop to prevent the code from using too many threads. What I did was replacing the `print threading.active_count()` line by this bit of code:

``````    # Print number of active threads.
exit_loop = True
while exit_loop:
The code halted (ie: got stuck inside the loop) when it reached `302` active threads. I waited for more than 10 minutes and the code never exited the loop and the number of active threads never dropped from `302`. Shouldn't the number of active threads diminish after a while?